Film canister to facilitate diameter sensing

ABSTRACT

A film canister with non-contacting means for indicating and facilitating sensing and calculation of film roll diameter and length of film left in the canister, and providing indication of film-out. The system for sensing the roll diameter comprises the canister, an inductive sensor and metered feed rollers. The system for calculating the film diameter and length and determining film-out comprises a microprocessor with visual indicating means.

FIELD OF THE INVENTION

This invention relates generally to a film storing and dispensing canister and more particularly concerns a means for indicating the diameter of the film roll within the canister, for calculating and displaying the amount of film remaining in the canister, and for indicating the absence of film in the canister.

BACKGROUND OF THE INVENTION

Accurate knowledge of the amount of film remaining in a film canister is important for camera systems used for computer output microfilm. These camera systems are typically connected either to a host computer, a magnetic tape drive, or some other equipment which has stored blocks of data which are to be printed on the film by the camera system. These data blocks vary in size and anywhere from a few feet to several hundred feet of film may be required to print the data. It is important to know the length of film remaining in the canister before the printing of a block of data is started so that there is enough film in the canister to print the complete block. This will allow the user to load a new full roll of film rather than have to splice the film in the middle of a data block.

Another reason it is important to accurately know the length of film left is because some applications require that a substantial length of film be left unprinted at the very end of the film to facilitate threading into developer equipment. The accurate knowledge of length of film left allows the camera system to automatically stop when a predetermined amount of film is left and therefore prevent the loss of data due to exposure to light during the threading process.

Determining the amount of film in a film canister has either been inaccurate or inconvenient with prior art devices. Two methods have been used in the past. One device that visually indicates on the side of the canister the amount of film left in the canister incorporates a lever mechanism which contacts the outside of the film roll. This provides only a relative reading with poor accuracy. The operator must stop the camera system and open the film bay area to read the amount of film left. This causes waste by exposing unprocessed film.

A second method is a meter-only system which allows for the display of film left information on an external device such as a CRT screen. It uses metered feed rollers to determine the amount of film removed from a canister having a predetermined starting length of film. This system simply subtracts the amount of film metered out from the known starting length. This method, due to accumulating metering errors, provides relatively poor accuracy as the canister approaches empty. The accuracy of this method also can be seriously degraded by "soft" errors of the system (hardware or software) which lose blocks of metering data. Additionally, this method is inconvenient because canisters are sometimes removed before the film in them is used up. This requires that the amount of film left in a partially used canister, as determined by the metering system, be written on the canister. The recorded length of film remaining in the canister must be manually entered into the system when that canister is inserted or reinserted.

SUMMARY OF THE INVENTION

It is an object of this invention to provide a film storing and dispensing canister which has a simple and accurate means for indicating the diameter of the film stored therein and means for indicating when a canister is out of film. The film canister consists of an enclosing shell formed of light opaque, non-electrically conductive material with a rotatable spool core, which has film wound on it, mounted inside and has a field modulating disk as part of the spool or mounted to it on one side. The disk would typically be maintained inside the canister to prevent handling damage, but could alternatively be mounted on the outside.

When incorporated in a system for employing the indicating means, which system includes a sensor, a metered feed roller assembly and a digital computer, together with the canister, the system can measure the diameter of the film roll from which it calculates and displays the length of film left in the canister.

The sensor, typically located externally of the canister, detects the completion of each rotation of the spool while a metered feed-roller assembly pulls the film from the canister in a precise fashion. This provides a means for measuring the length of film being fed out of the canister for each rotation of the spool.

The diameter of the film roll is calculated by a digital computer using the fundamental relationship between the diameter and circumference of a circle. The accuracy of this calculation is limited only by the accuracy of the metering roller and is independent of feed rate, timing, or canister construction tolerance. The use of a digital computer facilitates the determination of a film-out condition and allows for compensation for various factors including the ability to average as many readings as necessary to eliminate the effect of random errors. Given the spool core diameter and the film thickness, a digital computer can easily calculate the length of film left on the spool.

BRIEF DESCRIPTION OF THE DRAWING

The objects, advantages and features of the invention will be more readily perceived from the following detailed description when read in conjunction with the accompanying drawing, in which:

FIG. 1 is sectional side view of a film canister constructed in accordance with the invention;

FIG. 2 is an end sectional view taken along cutting plane 2--2 of FIG. 1;

FIG. 3 is an end sectional view similar to FIG. 2 of an of the canister;

FIG. 3A is a partial sectional view similar to FIG. 3 showing an alternative embodiment of the disk and hub configuration;

FIG. 4 is a block diagram of the sensing and calculating means of the invention; and

FIG. 5 is a logic flow diagram showing how roll diameter and length of film left are determined from input variables.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

With reference now to the drawing, and more particularly to FIGS. 1 and 2 thereof, there is shown film canister 11 having internal hubs 12 and 13 projecting inwardly from front and back sides 14 and 15 respectively of enclosure shell 18. The rectangular canister or film box is completed by top and bottom walls 16 and 17 and end walls 21 and 22. In actuality the canister will be formed of two or more segments which are assembled around the film roll in a light tight shell which is continuous except for the exit slot defined by sealing elements 31. Further, the canister may have any appropriate shape other than rectangular.

Typically the canister shell would be entirely made of electrically non-conductive material, such as a thermo-plastic, so as to allow the unimpeded transmission of (non-visible) electromagnetic fields to the field modulating disk. However, this limitation would not apply if the disk is mounted outside the canister. Further, the above limitation is actually only necessary in the immediate vicinity of the location of the external sensor, so that the remainder of the canister could be made of any light opaque material.

Rotatably mounted to projections 12 and 13 is spool core 23. The mating rounded surfaces of the projections and the spool provide appropriate bearing surfaces. The film tension during feed and the roll over-travel at the end of a feed cycle can typically be controlled by proper selection of hub projection material and diameter without the need for any external spindle, drive or brake means, or any additional internal friction reducing means. However, any of these could be employed where more precise tension is required.

Mounted on one end of spool 23 is field modulating disk 24. This disk is shown as being made of metal formed with spaced cutouts 25. The metal between the cutouts modifies an electromagnetic field and causes a change of state in a sensor. The disk could alternatively be made of a non-conductive substance having conductive elements attached thereto, equivalent to the space between cutouts 25. Disk 24 could be formed integrally with the spool. Other constructions of the disk are also possible. For example, the disk could be made or surfaced with a conductive material with recesses, discontinuities or convolutions that act like cutouts. The important feature is that, rotating with the spool core and film roll at a radius corresponding to where a sensor can be placed and within close proximity to the sensing location are two or more areas of differing interactivity with an external electromagnetic field, the transition of which may be detected by a sensor. It should be noted that for purposes of this invention, only one cutout or sensor interrupt is required but several are shown as they may be usefully employed to provide an average of multiple readings in a time efficient manner. Cutouts 25 are only as wide as necessary to have a transition from conductive to non-conductive which is detectable. It need only be a fraction of the angular width of the disk. Likewise the spaces between the cutouts need only be wide enough for the sensor to detect a transition from non-conductive to conductive.

Wound on spool 23 is film roll 26 which is pulled out of the canister as film 27 through light sealing elements 31 by metered feed-roller assembly 32. The feed-roller assembly comprises rollers 34 and 35, one of which has a known, accurate circumference and is coupled to stepper motor 43 which is driven by stepper motor drive circuit 44 (FIG. 4). Positioned externally of canister 11 is sensor 36 electrically connected to appropriate calculating means through wire 37 (see FIG. 4).

Sensor 36 may be of the inductive type which generates an oscillating magnetic field. When the conductive areas of disk 24 get close enough to the sensor, the change in magnetic field causes electrical eddy currents to flow in the disk material. This causes a change, such as a reduction in the amplitude or the frequency, or both, of the oscillating field, which results in a change in output voltage of sensor 36. As film is pulled out of the canister by the metered feed-roller assembly, the film roll and field modulating disk are rotated together. The spinning disk alternately presents conductive (or electromagnetically reactive) and non-conductive (or electromagnetically non-reactive) areas in proximity with the sensor. Every time there is a transition from non-conductive to conductive areas of the disk, that is, at the trailing edge of a cutout, for example, the sensor is activated and it causes an interrupt of the computer. When the disk continues to rotate so that no conductive areas are near the detector the computer interrupt is reset. Because the canister is made of opaque, non-conductive materials, it provides an effective light seal but does not interfere with the detector field in this situation. As stated above, the computer uses the length of film metered out by the feed-roller assembly between interrupts to generate a number which is proportional to the diameter of the film roll in the canister.

An alternative embodiment of the film canister is shown in FIG. 3. It functions in a manner identical with the canister of FIGS. 1 and 2 but the hub configuration is different. Core 23 is formed with hub extensions 19 and 20 which extend into canister projections 28 and 29 respectively. The bearing structures permitting relatively free rotation of the core and film roll in the canister are the same or equivalent to those already discussed.

FIG. 3A shows a disk and hub configuration for the canister which connects the external disk for rotation with the inner spool. Hub 55 is extended further through canister projection 56. A light tight seal is provided between hub 55 and projection 56 by conventional means. Disk 57, configured with segments to provide a sensor with signal changes, as before, is secured to hub 55 in some appropriate way for rotation therewith. This enables optical position detection for the rotating disk, in addition to other types of detection by appropriate sensor means.

The system for calculating the diameter of the film roll and the amount of film remaining on the spool is shown in FIG. 4. Computation and control means 41 is typically a microprocessor. The microprocessor logic modules include feed roller controller 42 which controls the metered feed-roller assembly 32 through stepper driver circuit 44 and stepper motor 43 based on directives received from camera system controller 53. This meters a given amount of film through the metered feed-roller assembly which pulls film from the film roll, causing the field modulating disk to turn. The field modulating disk causes the rotation sensor to change output state as conductive area transitions pass by.

Interrupt circuit 45 generates a program interrupt signal when a leading (or, alternatively, a trailing) edge of the sensor output signal is detected. Upon detecting this program interrupt the feed roller controller provides to diameter calculation means 46 the number of steps that the film has been fed since the last interrupt. The diameter of the film enclosed within opaque canister 11 is provided by the following equations: ##EQU1##

where D is the diameter of the film roll,

C_(R) is the circumference of the film roll and is equal to the length of film metered out for one full rotation of the field modulating disk

N is the number of motor steps driven for one rotation of the field modulating disk

S is the number of motor steps for one revolution of the motor, and

C_(F) is the circumference of the feed roller.

Calculating element 46 utilizes an algorithm based on Eqs. 1 and 2 that uses the average of the feed lengths from complete revolutions of each of the multiple slots of the field modulating disk. The averaging of multiple revolution data greatly reduces the error caused by random sensing variations. The use of only full revolution data in the calculations eliminates errors due to tolerances in field modulating disk construction. The logic used by element 46 to accurately calculate the film roll diameter, the length of film left, and to compensate for roll coast is given in the "Logic For Roll Diameter and Length Left Calculation" section below.

Bar codes are widely available to provide information and film canisters are no exception. Useful pertinent information about the canister and the film mounted in it is represented on bar code label 81 (FIG. 4) which is read by conventional bar code reader 82. Bar code evaluation circuit 83, which may be a logic module in the microprocessor, provides to film left calculator 48 information regarding several canister variables. This is done by analyzing two information fields within the number read from the canister bar code when a film canister is first placed in the camera system. The film type field identifies the core diameter, full film length and nominal film thickness. The unique canister identification field is compared with the identification numbers stored for previously used canisters to determine if the canister has been used before and has a calibrated film thickness value stored. If so, it provides that information to calculate block 48. If not, it provides canister variable information to film thickness calibrate block 84 which is enabled for that purpose.

Lot-to-lot variation in film thickness can be a significant source of error in estimating the length of film left (using Equation 4 below) for canisters that are nearly full. While this error goes to zero as the film is used up, an algorithm is provided which greatly reduces this error based upon knowledge of full canister film length.

Film thickness calibrate block 84 calculates the calibrated film thickness from the full film length and the roll diameter provided by calculate block 46 employing the equation: ##EQU2##

where t is the calibrated film thickness

L_(f) is the full roll film length, and

d is the core diameter.

The calibrated film thickness value is automatically stored in non-volatile memory.

Length-of-film-left block 48 uses the roll diameter provided by block 46, the core diameter provided by bar code evaluation block 83, and the film thickness provided by either bar code evaluator 83 or film thickness calibrate block 84 to calculate the length of film left in the canister using the equation: ##EQU3## where L is the length of film left.

This length left information is updated to display interface 85 after each interrupt, and can be displayed on visual display 43, which is typically a CRT. The length left value is stored in non-volatile memory whenever a canister is removed from the system.

Film out monitor 52 has two methods by which it detects a film-out condition. First, when all the film has been unwound from the core, the core and disk stop rotating. The system monitors feed roller controller 42. If more than a predetermined length of film is fed without an interrupt (from the rotation of the field modulating disk) being detected (indicative that the film has come loose from the core), a message is posted to the display interface which causes a film-out message to appear on the visual display. The camera is then stopped at the earliest convenient time by monitor 52.

The second film-out detection method is used, in conjunction with the first method, on those systems where the accuracy of the point where the film comes loose from the core is not as precise as the film left estimate. In this case film-out monitor 52 monitors the value of the film left on line 51 from calculator 48. When this value approaches a specific point where the film may start to slip on the core, film out monitor 52 takes over the estimation of the length of film left by subtracting the amount of film fed by feed roller controller 42 from the last reliable film left value. When this estimate of film left goes to zero a film-out message is posted to the display interface and the camera is stopped. For situations where a substantial unprinted "tail" length of film is required, the film left estimate would be compared to the desired tail length instead of zero.

The first film-out detection method is needed in conjunction with the second in order to handle various circumstances such as when the operator changes to a different canister type (with a different core diameter) without notifying the system (through the bar code) of the change.

Employing the film canister to facilitate diameter sensing in this invention has several significant advantages over known prior art devices. It provides a simple and inexpensive means for indicating the diameter of the film on a spool in an opaque canister. The type of diameter indication used has inherently high accuracy, being insensitive to most manufacturing tolerances within the unit. Furthermore, it provides a positive film-out indicator, eliminating the need for auxiliary sensors for this purpose.

There are three basic configurations of the system of this invention to estimate the film left using the film canister to facilitate diameter sensing. Each of these configurations has distinct advantages over prior art systems and devices and shows the usefulness of a film canister containing a field modulating disk. The three configurations could be described as having the characteristics of (1): the complete system described above; (2) the complete system but without a canister bar code label and bar code reader; and (3) the complete system but without the bar code enhancement and without means for calibrating film thickness.

All three of these systems provide better accuracy than is provided by a lever mechanism incorporated with the film canister and they avoid opening the camera bay to determine the length of film left. Another advantage of the systems of this invention is that they prevent waste of film. None is lost by unintended exposure because there is no need to open the camera bay to check film length. Because the invention determines when the film on the core is at the end, no film is thrown away due to an unknown small amount of film which may remain, which could be the result with prior, less accurate film length determining systems. All of the embodiments of the invention allow for the elimination of a separate "film-out" sensor because it is able to detect when the film comes loose from the spool core and because of the inherently high film left accuracy when the film is nearly expended. All of these embodiments also permit removal and replacement of film canisters without writing down or reentering intermediate film-left data.

System (2) above additionally has superior overall film left estimating accuracy than a meter-only system. Because the film thickness calculation uses the predetermined full canister film length, it causes the accuracy of the output for a full (or nearly full) roll to be equivalent to a similar meter-only system. However, as film is removed from the roll of system (2) the accuracy can actually improve and is superior to a meter only system because in this system there is no accumulation of feed-length errors. If the calibrated accuracy should be lost for some reason, the accuracy reverts to equivalence to system (3).

System (1) above eliminates the need by the operator (in system (2)) to specify the type of film and whether or not it is a full roll (for calibration) when a canister is placed in the camera system. This also allows calibration accuracy to be maintained if a roll is removed and replaced and allows the determination of the amount of film in a canister before it is placed in the camera system by reading the canister bar code and the last film-left data stored corresponding to the unique identification field for that canister. While a meter-only system could theoretically also incorporate a canister bar code and bar code reader, it would still provide inferior film-left accuracy, require an additional film-out sensor, and would be more susceptible to certain kinds of soft system errors that cause loss of metering data.

It was previously mentioned that the disk could be inside or outside the canister body. If it is outside, there are alternative sensing means which become available. For example, optical sensors could be used with an external disk. The means for coupling an external disk to the spool core could be a physical direct connection or a magnetic coupling, among others.

LOGIC FOR ROLL DIAMETER AND LENGTH LEFT CALCULATIONS

The flow diagram of FIG. 5 shows the flow of information between the variables used by calculating element 46 to give a highly accurate estimate of the roll diameter and the length of film left. With respect to FIG. 5, the assumption is made that there are eight encoder slots or predetermined detectable changes around the disk. The use of multiple slots allows for the averaging of more values sooner after start-up and hence more accuracy and early reduction of random errors. Using eight slots allows for the timely detection of a film out condition and assists in the elimination of coast errors by assuring that for the typical feed cycle of 148 mm any reading received during a coasting condition, due to roll inertia at the end of a feed cycle, will be followed by a good reading where film tension is maintained during a feed cycle.

Execution begins when sensor 36 detects a disk slot (step 61) when the disk is rotating. This provides an interrupt from circuit 45 to the system. The number of feed motor steps driven since the last detection is obtained from feed roller controller 42 in step 62. Steps 63-67 and 71 show the method used to reduce the error caused when a detection of a disk transition occurs after a feed cycle has stopped and the inertia of the roll has caused it to coast some unknown distance. This coast would cause the number of steps to be misleadingly low for this reading and high for the next following reading. Steps 64 and 65 average these two readings and set these readings equal to their average. Theoretically these values should differ by an amount corresponding to the difference in film roll diameters for these two different times. However, for typical values of film thickness and motor characteristics (steps per revolution) the reading difference would be less than one motor step and not significant. This logic requires that each reading be "buffered" or held back one cycle of logic, beginning at step 72, so that each reading can be processed with the next reading to correct for coast errors before any further calculations take place.

In step 72 each of the previous eight readings (read in the last eight logic cycles before the present reading) are added together in order to obtain the total number of steps for one full revolution of the disk.

In step 73 the last eight revolution totals (including the last) computed in step 72 during the last eight logic cycles are averaged and this average is multiplied by the distance the film moves for one feed motor step to obtain an average diameter. Because there are eight slots in the disk this average of eight revolution totals is obtained in just two rotations of the disk.

The average diameter of the roll is calculated simply by the relationship: ##EQU4## where "Step Size" (equal to C_(F) /S) is the length of film fed by the metered feed-roller assembly for one step of the feed-roller controller.

The estimated diameter of the roll at the instant of the last detection is obtained in step 74 by subtracting from this average the offset in diameter caused by one rotation f the disk (two thicknesses of film are removed from the diameter for each rotation).

The estimated length of film left on the roll is easily calculated in step 75 from the roll diameter as explained previously. This method for determining film roll diameter and film length reduces the need for precision in construction of the field modulating disk and at the same time it filters out random sensing and coast read errors.

In view of the above description, it is likely that modifications and improvements will occur to those skilled in the art which are within the scope of the accompanying claims. For example, under some circumstances it may be possible or desirable for the sensor to be located integrally within the shell. 

What is claimed is:
 1. A film canister to facilitate determination of length of film remaining after any usage and having a positive film-out indication means, said canister comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell for dispensing said film through said output slot; bearing means facilitating free rotation of said core within said shell; a disk within said shell having at least one element thereon detectable by means of an associated sensor positioned externally of said light-tight enclosure shell for sensing rotation of said disk relative to said shell; and means for coupling said disk to said core for rotation therewith.
 2. The film canister recited in claim 1, wherein said enclosure shell is made of opaque non-conductive material.
 3. The film canister recited in claim 1, wherein said disk is made of metal and is formed with at lest one non-conductive segment, the transition between the metal and said segment being electromagnetically detectable by the sensor.
 4. The film canister recited in claim 1, wherein said disk is made of non-conductive material and has at least one conductive element secured to the side thereof.
 5. The film canister recited in claim 1, wherein said detectable element is radially disposed from the center of said disk.
 6. The film canister recited in claim 1, wherein said disk is formed with surface discontinuities which are detectable by the sensor.
 7. The film canister recited in claim 1, wherein said disk is formed with surface convolutions which are detectable by the sensor.
 8. The film canister recited in claim 1, wherein said disk is mounted directly to said spool core within said shell.
 9. The film canister recited in claim 1, wherein said disk is integral with said spool core within said shell.
 10. The film canister recited in claim 1, wherein said disk has a plurality of said detectable elements arranged radially around the center of said disk.
 11. The film canister recited in claim 1, and further comprising a sensor disposed in operative relationship with said shell and said disk, said sensor being adapted to produce signals indicative of the rotary position of said core.
 12. The film canister recited in claim 5, and further comprising a sensor disposed in operative relationship with said shell and said disk, said sensor being adapted to produce signals indicative of the rotary position of said core.
 13. The film canister recited in claim 9, and further comprising a sensor disposed in operative relationship with said shell and said disk, said sensor being adapted to produce signals indicative f the rotary position of said core.
 14. The film canister recited in claim 10, and further comprising a sensor disposed in operative relationship with said shell and said disk, said sensor being adapted to produce signal indicative of the rotary position of said core.
 15. A system for determining the length of film remaining in a film canister, said system comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell for dispensing said film through said output slot; bearing means facilitating free rotation of said core within said shell; sensor means; a disk having at least one element thereon detectable by said sensor means; means for coupling said disk to said core for rotation therewith; said sensor means being external of said enclosure shell and being adapted to detect rotation of said core and disk within said enclosure shell and to provide a signal indicative of the position of said disk relative to said enclosure shell; film feed-metering means for precisely extracting a length of film from said canister, said feed-metering means comprising a pair of opposed pressure roller means engageable with respective opposite surfaces of said film, one of said pressure roller means having a predetermined circumference to facilitate precisely extracting said film from said canister; and computation and control means for providing a feed length control signal to said film feed-metering means, for determining, from the disk position signal in conjunction with said feed length control signal, the diameter of the film wound on said core, the length of film remaining in said shell, and for determining when the canister is empty.
 16. The system recited in claim 15, and further comprising visual display means for displaying the length of film remaining in said shell.
 17. The system recited in claim 15, wherein said computation and control means comprises:film out detector means for determining when the film on said spool core has been expended, said film out detector means generating a film out signal indicative of the end of available film in said shell; means responsive to said film out signal for stopping use of the film from said canister.
 18. The system recited in claim 17, wherein said film out detector means generates said film out signal when said film-metering means is driven to feed film but said sensor means provides no signal indicating motion of said disk.
 19. The system recited in claim 17, and further comprising:a signal output from said computation and control means indicative of the length of film remaining in said shell; and means for applying said length of film remaining signal to said film out detector means; said stopping means operating when the calculated length of film remaining goes to a predetermined minimum value.
 20. A method for determining the length of film mounted on a spool in an enclosure shell, the shell being light-tight, the spool being mounted for free rotation within the shell, said method comprising the steps of:coupling a disk within said enclosure shell to the spool, the disk having spaced detectable elements thereon and rotating with the spool; feeding a length of film out of the enclosure shell; measuring the length of film fed out of the shell; while electromagnetically sensing the rotation of the disk from externally of said enclosure shell by sensing said detectable elements; providing a signal indicative of the position of the disk; calculating the diameter of the film on the spool in the shell; and calculating the length of film left on the spool in the shell.
 21. The method recited in claim 20, and comprising the further step of visually displaying the length of film remaining.
 22. The method recited in claim 20, and comprising the further steps of:determining when the film in the shell has been expended; and generating a signal indicative that the film has been expended.
 23. The method recited in claim 22, and comprising the further step of stopping use of the film from the canister.
 24. The method recited in claim 20, and comprising the further step of calculating the thickness of the film in the shell.
 25. The method recited in claim 20, whereinsaid feeding step comprises advancing said film between a pair of opposed pressure roller means engageable with respective opposite surfaces of said film, wherein one of said pressure roller means has a predetermined circumference to facilitate effecting said measuring step with precision.
 26. A system for determining the length of film remaining in a film canister, said system comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell; bearing means facilitating free rotation of said core within said shell; sensor means; a disk having at least one element thereon detectable by said sensor means; means for coupling said disk to said core for rotation therewith; said sensor means being external of said enclosure shell and being adapted to detect rotation of said core and disk and to provide a signal indicative of the position of said disk; film feed-metering means for precisely extracting a length of film from said canister; and computation and control means for providing a feed length control signal to said film feed-metering means, for determining, from the disk position signal in conjunction with said feed length control signal, the diameter of the film wound on said core, the length of film remaining in said shell, and for determining when the canister is empty, said film feed-metering means comprising a stepper motor coupled to a roller which drives the film from said canister, said roller having a calibrated circumferential length whereby each full rotation of said roller or partial rotation corresponding to a discrete number of steps of said stepper motor provides a precise value of the length of film from said canister.
 27. A system for determining the length of film remaining in a film canister, said system comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell; bearing means facilitating free rotation of said core within said shell; sensor means; a disk having at least one element thereon detectable by said sensor means; means for coupling said disk to said core for rotation therewith; said sensor means being external of said enclosure shell and being adapted to detect rotation of said core and disk and to provide a signal indicative of the position of said disk; film feed-metering means for precisely extracting a length of film from said canister; and computation and control means for providing a feed length control signal to said film feed-metering means, for determining, from the disk position signal in conjunction with said feed length control signal, the diameter of the film wound on said core, the length of film remaining in said shell, and for determining when the canister is empty, wherein the diameter of the film wound on said core within said shell is calculated by the equation; ##EQU5## where D is the calculated diameter of the film roll, and C_(R) is the length of film metered out for one rotation of the disk.
 28. A system for determining the length of film remaining in a film canister, said system comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell; bearing means facilitating free rotation of said core within said shell; sensor means; a disk having at least one element thereon detectable by said sensor means; means for coupling said disk to said core for rotation therewith; said sensor means being external of said enclosure shell and being adapted to detect rotation of said core and disk and to provide a signal indicative of the position of said disk; film feed-metering means for precisely extracting a length of film from said canister; and computation and control means for providing a feed length control signal to said film feed-metering means, for determining, from the disk position signal in conjunction with said feed length control signal, the diameter of the film wound on said core, the length of film remaining in said shell, and for determining when the canister is empty, wherein the length of film remaining in said shell is determined by the equation: ##EQU6## where d is the core diameter t is the film thickness and L is the estimated film left.
 29. A system for determining the length of film remaining in a film canister, said system comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell; bearing means facilitating free rotation of said core within said shell; sensor means; a disk having at least one element thereon detectable by said sensor means; means for coupling said disk to said core for rotation therewith; said sensor means being external of said enclosure shell and being adapted to detect rotation of said core and disk and to provide a signal indicative of the position of said disk; film feed-metering means for precisely extracting a length of film from said canister; and computation and control means for providing a feed length control signal to said film feed-metering means, for determining, from the disk position signal in conjunction with said feed length control signal, the diameter of the film wound on said core, the length of film remaining in said shell, and for determining when the canister is empty, said computation and control means further comprising film thickness calibration means which determines the thickness of the film in said canister according to the equation: ##EQU7## where t is the film thickness L_(f) is the full roll film length D is the calculated film roll diameter, and d is the core diameter.
 30. A system for determining the length of film remaining in a film canister, said system comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon and rotatably mounted within said shell; bearing means facilitating free rotation of said core within said shell; sensor means; a disk having at least one element thereon detectable by said sensor means; means for coupling said disk to said core for rotation therewith; said sensor means being external of said enclosure shell and being adapted to detect rotation of said core and disk and to provide a signal indicative of the position of said disk; film feed-metering means for precisely extracting a length of film from said canister; computation and control means for providing a feed length control signal to said film feed-metering means, for determining, from the disk position signal in conjunction with said feed length control signal, the diameter of the film wound on said core, the length of film remaining in said shell, and for determining when the canister is empty; and a bar code label on said canister, said label representing information regarding the film in said canister including full length and the nominal thickness of the film in said canister and the diameter of said core, said bar code label having a different identification number for each canister; a bar code reader; bar code evaluation circuit means; means for coupling said bar code evaluation circuit to said computation and control means to facilitate determination of film roll diameter and length of film remaining on said spool core.
 31. A method for determining the length of film mounted on a spool in an enclosure shell, the shell being light-tight, the spool being mounted for free rotation within the shell, said method comprising the steps of:coupling a disk to the spool, the disk having spaced detectable elements thereon and rotating with the spool; measuring the length of film fed out of the shell; while sensing the rotation of the disk; providing a signal indicative of the position of the disk; calculating the diameter of the film on the spool in the shell; reading bar code information from the shell regarding full length and nominal thickness of the film in the shell, the diameter of the spool, and the shell identification number; evaluating the information read from the bar code; providing a signal representative of the bar code evaluated information; and coupling the bar code evaluated information signal to calculation and control means to facilitate determination of film roll diameter and length of film remaining on the spool.
 32. A film canister to facilitate determination of a length of film remaining after any usage, said canister comprising:a light-tight enclosure shell having a film output slot; a spool core adapted to hold a quantity of film wound thereon for dispensing the film through said output slot, and bearing means for rotatably mounting said spool core within said shell for rotation of said core therein; and disk means coupled with said spool core within said enclosure shell for rotation with said spool core, said disk means comprising at least one non-conductive region and at least one conductive region to facilitate electromagnetically sensing rotation of said disk means and said spool core relative to said enclosure shell; said light-tight enclosure shell including at least a portion comprising non-conductive material to permit electromagnetically sensing of the rotation of said disk means from the exterior of said light-tight enclosure shell.
 33. The film canister recited in claim 32, wherein said disk means comprises non-conductive material, and has at least one conductive element secured thereto spaced radially from a rotational axis of said disk means, said conductive element providing said conductive region of said disk means.
 34. The canister recited in claim 32, wherein said enclosure shell is formed from non-conductive material. 